Browsing by Subject "greenhouse gases"
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Item Open Access Analysis of Upstream Sustainability Trends Within the Food Production Industry(2013-04-23) Lam, Jessica; Dallas, Sarah; Stabert, NoraSarah Dallas, Jessica Lam, and Nora Stabert analyzed sustainability trends among U.S. pasta manufacturers with Philadelphia Macaroni Company (PMC) as a case study. PMC, founded in 1914, is a private, pasta manufacturer with an annual capacity of over 170 million pounds of pasta. It sells to customers including but not limited to the Campbell Soup Company, Annie’s Homegrown Pasta, and General Mills. Recently, PMC has been contacted by top customers regarding sustainability and recognizes the growing trend within the industry. This master's project advises the company on the definition of sustainability as it applies to PMC and recommends an approach for sustainability in the future. This project provides a comprehensive overview of the penetration of sustainability for pasta manufacturers, evaluation of PMC's current operations, the expectations of its customers, and the prioritization of sustainability by its top competitors. The final deliverables are (1) market analysis of key competitors, (2) current sustainability initiatives amongst PMC's customers, (3) customized greenhouse gas calculation tool, and (4) analysis of supply chain actors and interactions.Item Open Access Assessing the Effects of Management Activities on Biodiversity and Carbon Storage on Public and Private Lands and Waters in the United States(2023-04-13) Warnell, Katie; Mason, Sara; Karasik, Rachel; Olander, Lydia; Posner, Stephen; Alonso-Rodríguez, Aura; Aristizábal, Natalia; Bloomfield, Laura; Estifanos, Tafesse; Gourevitch, Jesse; Littlefield, Caitlin; Mazurowski, Jason; Menice, Katarina; Moore, Maya; Nicholson, Charlie; Sands, Bryony; Spencer, Leslie; Treuer, Tim; Ricketts, Taylor; Hartley, ChrisNatural and working lands (NWLs) provide many benefits to people, including storing greenhouse gases (GHGs), supporting biodiversity, and generating other ecosystem services. Management of NWLs can influence their condition and function and therefore the benefits they provide. This project surveys the synthesis literature to assess how different management actions on various types of NWLs affect biodiversity and GHG outcomes. This information can help to determine how to best manage these lands to contribute to both biodiversity and climate solutions in the United States. These results are a starting point to assess how different forms of management on various types of NWLs contribute to or detract from biodiversity and GHG outcomes. Though this study’s scope was limited to an exploration of biodiversity and GHG benefits provided by NWLs, this process could be adapted to examine the effects of management on other important ecosystem services, as well as how management affects equitable distribution of those services. Additional quantitative synthesis is also needed to compare the magnitude of different management activities’ impacts on biodiversity and carbon and to better understand how the intensity of certain activities influences these outcomes. This report is a collaboration between the Nicholas Institute for Energy, Environment & Sustainability and the Gund Institute for Environment at the University of Vermont. This research was supported by the US Department of Agriculture, Office of Environmental Markets, under a cooperative agreement. The findings and conclusions in this report are those of the authors and should not be construed to represent any official USDA or US Government determination or policy. For related work, please see Tracking the Benefits of Natural & Working Lands in the United States: Dataset Evaluation and Readiness Assessment.Item Open Access City of Greenville, NC Greenhouse Gas Accounting and Emissions Reduction Plan(2022-04-22) Rosenthal, Regan; Patchett, MaggieAs we near the International Panel on Climate Change’s 2030 deadline to halve global greenhouse gas (GHG) emissions, cities are being called upon to proactively manage the negative effects of urbanization. Greenville, North Carolina aims to join the growing list of American cities who are taking responsibility for their role in climate change by generating a comprehensive inventory of the GHGs emitted by their municipal operations. Our team’s objective was to catalog the city’s greenhouse gas footprint and make recommendations according to our findings, working in coordination with the City Manager of Greenville, NC. Specifically, we were tasked with creating an emissions inventory that could be used as the city’s baseline, against which future years’ inventories could be measured and compared to track reductions over time. We produced a baseline GHG emissions inventory of municipal operations from fiscal year 2019, as that was the most recent fiscal year which experienced no operational interruptions from the Covid-19 pandemic. The inventory identifies activities and sectors with high emissions contributions, and we used this data to recommend the emissions reductions measures that would be most beneficial to the city. Our GHG emissions accounting methodology utilized the standardized framework for local governments created by ICLEI’s Cities for Climate Protection Campaign. Using ClearPath—ICLEI’s GHG emissions inventory tool—we generated an emissions report which includes an emissions inventory, projections of future emissions, and forecasts that predict the effects various potential reduction measures might have on Greenville’s GHG footprint over a 10-year period. The emissions report contributed to the development of a sustainability project work plan with benchmarks and targets to track municipal emissions reduction performance over time. Key Findings: 1. The majority of Greenville’s emissions are Scope 1, or direct emissions from operational activity. 2. The greatest contributing sector of municipal operations to the city’s emissions inventory is Vehicle Fleet. In this instance, “Vehicle Fleet” encompasses both municipal vehicles and transit vehicles, though future inventories should distinguish between the vehicle types to better target possible areas for emissions reductions. 3. Greenville’s emissions per capita for municipal operations are not directly comparable to other North Carolina municipalities. The City of Greenville does not have operational control over some activities and sectors included in their peers’ inventories of government operations. Key Recommendations: 1. Implement energy efficiency improvements within Greenville’s vehicle fleet to reduce the sector’s contribution and the overall emissions footprint for municipal operations. 2. Disaggregate data into individual records within ClearPath to better understand which activities by sector have the largest contribution to better select emissions reduction measures. 3. If data is available, use the same process to generate a 2005 emissions inventory for the purposes of setting goals and measuring progress. 4. Continue the momentum from this project by making sustainability a permanent fixture within city operations through the hiring of a sustainability professional.Item Open Access Integrating Life Cycle Assessment in AT&T's Product Eco-Rating System(2015-04-24) Barrs, DanielleAT&T Inc. is an American communications holding company whose subsidiaries and affiliates are providers of AT&T services, including wireless services. In connection with its Citizenship & Sustainability (C&S) efforts, AT&T requires that wireless devices carrying its brand be rated based on a number of environmental factors. These factors are assessed and devices are given an eco-rating of 1-5 stars. Now, AT&T is looking to incorporate life cycle assessment (LCA) into this product eco-rating system. This Master’s Project serves as a reference guide to assist AT&T in the integration of LCA in their eco-ratings. It also serves as the foundation for a business strategy roadmap which leverages the incorporation of LCA in corporate sustainability initiatives. This enhances transparency, reliability and innovation – not only as it relates to the company itself, but in helping consumers and other organizations forge a more sustainable future in an ever-evolving world. This report begins with an overview of sustainability initiatives at AT&T, followed by a breakdown of the company’s product eco-rating system. Subsequent sections consist of an LCA overview and roadmap, an analysis of emerging trends in the ICT industry with regards to life cycle and impact assessment, and recommendations for further development of AT&T’s C&S efforts in this regard.Item Open Access Rural Investment: Building a Natural Climate Solutions Policy Agenda that Works for Rural America and the Climate(2020-06-03) Bonnie, Robert; Vujic, Tatjana; Plutshack, Victoria; Arata, ShannonRural America—particularly its farms, ranches, and forests—is vital to solving climate change. Forests absorb the equivalent of 11–15 percent of U.S. greenhouse gases (GHGs) while agriculture accounts for about 9 percent of U.S. GHG emissions. Under any reasonable scenario, meeting aggressive climate goals will require farmers, ranchers, forest owners and public land management agencies to prioritize climate mitigation across hundreds of millions of acres. Success will require new federal policies and, importantly, accelerated and substantial increases in public and private investment in land management practices that sequester carbon and reduce GHGs. That won’t happen without the combined support from rural voters and agricultural and forestry stakeholders. This report outlines a menu of policy ideas capable of both garnering the necessary support from rural America and helping the U.S. reach its climate goals through natural climate solutions. This report arrives at this menu of policies by focus on four questions: (1) Where are the tons? Which agricultural and forestry practices result in the most significant GHG emissions reductions and sequestration, and where are those practices likely to occur? (2) Where are the stakeholders? What are the positions of stakeholders in agriculture, forestry, hunting and fishing, outdoor recreation, and environment/conservation with regards to climate policy on agricultural and forest lands? (3) What can we learn from state experience with natural climate solutions? (4) What suite of federal policies could get the necessary GHG reductions and win rural support?Item Open Access Spatial and Temporal Scaling in Ecohydrology: A Case Study of Soil Greenhouse Gas Fluxes From a Subalpine Catchment(2017) Kaiser, Kendra ElenaGlobal climate change is largely due to human induced increases in the emission of greenhouse gases to the atmosphere. Although this fact does not directly motivate this research, it does set the backdrop for the impressive increase in research that topic has garnered across disciplines over the past 30 plus years. The goals of the research presented herein were to investigate the spatial and temporal dynamics of carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O) flux dynamics in a snowmelt dominated, semi-arid watershed in central Montana and to assess if and how these fluxes were related to patterns imposed by the topographic structure of the watershed. In the process, it has become apparent that a conceptual model that incorporates all three of these important GHGs, and their relationships with environmental variables does not exist. This is certainty at least in part due to the high variability of these fluxes within and between ecosystems. However, a concise conceptual model is necessary to compare empirical evidence and test alternative scaling methods across systems. Explicitly incorporating hydrologic processes into a conceptual framework will not only be important, but imperative, to predicting and assessing responses of these biogeochemical fluxes to a changing climate. This will be particularly relevant in locations that are likely to experience a change in the timing of precipitation such as snow versus rain dominated in sub-alpine zones or change in the timing and frequency of rain events.
In this study, we assessed the spatial and temporal dynamics of three major GHGs using a spatially distributed sampling campaign over two growing seasons. Real time sensors (5 locations) and local spatial variability plots (700 m2, n = 7, with 30 samples in each) were nested within a landscape scale sampling design (n=52). The sites that were distributed across the landscape (n = 52) were organized by transects that either exemplified specific landscape elements (e.g. uplands vs riparian area) or crossed significant environmental gradients (e.g. riparian – uplands or clearcut – forest). Total annual precipitation was similar between the two focal years (2012 = 764 mm 2013 = 749 mm). However, the contribution from rain versus snow shifted from 76% snow and 24% rain in 2012 to 56% snow and 44% rain in 2013. The influential rain events in 2013 began on 17 July and were observed through 14 August.
In this study, we observed that the strength of the relationship between soil water content and topographic metrics of water redistribution increased as the average wetness of the watershed declined. Soil water content and CO2 flux (fCO2) exhibited distinct spatial and temporal variability at the plot and landscape scales in 2013. The legacy effects of clearcutting remained prevalent with regards to fCO2 (which was significantly higher in the forest than in the clearcut regrowth), while differences in the spatial and temporal variability of \theta were not evident between the two landcover types.
Relationships between fluxes of CO2, CH4, and N2O and \theta were variable. The relationship between each gas and soil water content was not consistent between riparian and upland landscape elements. Although the transition zone between riparian and upland locations has been a focal point in watershed biogeochemistry, it appears that focusing on the shifting hydrodynamics, or the dominant hydrologic processes themselves, might be more important than focusing on specific, pre-defined locations in the landscape.
We capitalized on the significant relationships between terrain mediated \theta in the uplands and cumulative seasonal flux of CH4 to empirically scale our weekly measurements of CH4 flux to the watershed scale. We determined that incorporating multiple terrain metrics in the model produced the strongest fit between modeled and observed CH4 flux. This scaling exercise showed that the best fit model predicted over twice as much CH4 consumption in the uplands than predicted with an individual topographic wetness index or by extrapolating the mean/median CH4 flux to the watershed. Additionally, we determined that even if we used the maximum value of seasonal CH4 efflux in the riparian area to estimate riparian contributions, the riparian CH4 efflux only constituted 1– 4% of the net watershed CH4 flux (depending on which value of net influx is used).
While searching for the mechanisms that create biogeochemical optima can interesting and valuable, moving forward, it seems equally important to investigate the spatiotemporal dynamics of fluxes (or times/ places) that we expect to exhibit more landscape scale characteristic levels of a given flux/pool/process. It is also critical that we do not treat the hydrologic dynamics that can influencing those pools/fluxes as a “black box”. Field studies that measure these hydrologic dynamics can provide rich data sets to test accepted and proposed conceptual models and provide useful calibration data for process-based models. The combination of these techniques will most certainly advance our understanding of the spatial and temporal dynamics of greenhouse gas fluxes across given systems. However, evolved conceptual models will be key to assessing how each unique field site or modeling exercise contributes to greater process understanding and predictive capacity. Here we contribute to an updated conceptual model of the relationship between the processes that influence these GHG fluxes and soil water content. We hope that these conceptual contributions will spur new research questions that span systems and scales, while the empirical contributions highlight a few ways that this can be done in practice.